The differences between J–V plots o

The differences between J–V plots of the fabricated DSSCs in Fig. 5 are related to the amount of anthocyanin bound to TiO2 surface. Since the dye matrix affects the amount of desirable anthocyanin bounded to TiO2 surface, the SPE was carried out to achieve high anthocyanin content by reducing the undesirable contamination components such as phenolics, proteins, polysaccharides polysaccharides, and other flavonoids. SPE with sorbents consisting C18 chains bonded on silica has been generally considered to be the most effective method for anthocyanin purification [26]. Rodriguez-Saona and Wrolstad described the basic protocol for anthocyanin pigment isolation using the C18, sorbent; indicating the production of relatively pure anthocyanin extracts [27]. In this study, anthocyanin-rich extract obtained from Siahkooti fruit was further purified by SPE (C18 Sep-Pak cartridge, 10 g capacity, Waters Corp., Milford, MA), preconditioned with methanol, followed by water. Table 1 shows the photoelectrical characteristic data obtained for the fabricated DSSCs based on the natural dye extracted from fruits of Siahkooti as natural sensitizer, (a) befor and (b) after purification using SPE. The photoelectric conversion efficiency of the cell based on the non-purified Siahkooti dye
extract and the DSSC fabricated using the purified dye extract by SPE were obtained as 0.27% and 0.32%, respectively. A short circuit current density (JSC) of 0.9 mA/cm2, open-circuit voltage (VOC) of 0.49 V, and a fill factor (FF) of 0.73 were obtained for the purified dye based DSSC. This improvement may be related to the increase in the amount of anthocyanin bound to TiO2 surface due to the reduction in the undesirable contamination components in the dye matrix.